Identification of inherent position-independent geometric errors for three-axis machine tools using a double ballbar with an extension fixture

This paper presents a double ballbar method with an extension fixture to identify the position-independent geometric errors of three-axis machine tools with respect to their entire workspace by conducting face- and body-diagonal length tests. To extend the length of the double ballbar to the require...

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Bibliographic Details
Published in:International journal of advanced manufacturing technology 2019-06, Vol.102 (9-12), p.2967-2976
Main Authors: Yang, Seung-Han, Lee, Hoon-Hee, Lee, Kwang-Il
Format: Article
Language:English
Subjects:
3-D printers
Advanced manufacturing technologies
Ballbars
CAE) and Design
Computer-Aided Engineering (CAD
Engineering
Error compensation
Industrial and Production Engineering
Machine tools
Mechanical Engineering
Media Management
Multiaxis
Original Article
Pitch (inclination)
Position measurement
Rolling motion
Straight lines
Three axis
Three dimensional models
Three dimensional printing
Uncertainty analysis
Yaw
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Summary:This paper presents a double ballbar method with an extension fixture to identify the position-independent geometric errors of three-axis machine tools with respect to their entire workspace by conducting face- and body-diagonal length tests. To extend the length of the double ballbar to the required nominal length in the face- and body-diagonal directions, an extension fixture is designed and manufactured using a fused-deposition-modeling 3D printer to ensure that it is lightweight. Inherent position-independent geometric errors can be calculated from measured lengths by using homogeneous transformation matrices, which are multiplied under the assumption of small values, to determine the volumetric error produced by a machine tool. The relationships between the position-independent geometric errors, roll-pitch-yaw errors, and measured lengths can be derived according to the definition of the straightness errors, based on the end-point of the reference straight line. Finally, the position-independent geometric errors, with analysis of measurement uncertainties, can be identified by substituting the values of the roll-pitch-yaw errors, measured by a multi-axis calibrator, into the derived relations. The results can then be validated by re-measuring the face- and body-diagonal lengths with error compensation. The main advantage of the proposed approach is that it can be used to identify the inherent position-independent geometric errors of machine tool workspaces. This could contribute to reducing volumetric errors in machine-tool workspaces by allowing compensation for measurement errors, thus making machine tools more effective.
ISSN:0268-3768
1433-3015
DOI:10.1007/s00170-019-03409-7